Optimization of electrical circuits

ABSTRACT

A user may optimize a circuit design using a control presented within an Internet browser. The user can change the optimization value of the circuit that in turn places more or less emphasis on a parameter (e.g. foot print vs. efficiency). Once optimized for the values, the list of components matching the design as well as the optimization operating values are presented to the user.

FIELD OF THE INVENTION

The present invention relates to electrical circuit simulations, andmore particularly to the modifying an electrical design.

BACKGROUND OF THE INVENTION

Many times when a user requires a circuit, the user frequently knowslittle more than the requirements that the circuit must satisfy. Toobtain the desired circuit, the user may provide a list of therequirements to a business that is knowledgeable about those types ofcircuits, how to design them, and where to obtain the components tofabricate them. The business may then construct and supply the user withthe circuit. The business may have a significant price mark up for theseservices.

To avoid having to pay the marked up prices, the user may attempt tobecome educated on circuit design, obtain parts catalogs from circuitcomponent suppliers, and fabricate the circuit. However, the effort andcost required to gain the requisite education and knowledge may not beworthwhile. To reduce the effort required to perform some of thesetasks, the user may obtain and install specialized off line tools, suchas the Switchers Made Simple software product available from NationalSemiconductor Corporation. While such tools may assist in the circuitdesign and component selection tasks, the user must still go through themanual process of placing orders for the components. Further, given therapidity with which circuit component manufacturers change their productlines, the component information used by the specialized off linesoftware will quickly become outdated unless frequently updated. Theinconvenience of having to obtain, install, and keep such specializedsoftware updated does not make this the solution ideal.

Electrical simulators typically allow a user to conduct an electricalsimulation of a pre-existing electrical schematic (or circuit). The usercan observe the performance of the circuit under simulated operatingconditions. The user can change simulation related parameters but mustuse a pre-defined reference circuit. Furthermore, the user cannot freelychange the connectivity of the circuit or add or remove components in afree form manner.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1-3 illustrate an exemplary environment for practicing theinvention;

FIG. 4 is a block diagram that gives an overview of functional modulesused to implement an embodiment of the invention;

FIG. 5 shows an overview flow diagram illustrating general steps of themodifying or creating a schematic;

FIG. 6 illustrates an exemplary web page for starting the designprocess;

FIG. 7 shows an exemplary requirements web page for receiving therequirement information from a user for a power supply circuit;

FIGS. 8A and 8 b are examples of a suggested component web pagegenerated in response to the requirements specified according to FIG. 7;

FIG. 9 shows an exemplary web page illustrating a product folder webpage;

FIGS. 10A and 10B illustrate an exemplary bill of materials web page;

FIGS. 11A and 11B illustrates an exemplary web page showing choices ofalternate components for a component;

FIGS. 12A and 12B show exemplary web pages illustrating operating valuesof a circuit;

FIG. 13 shows an exemplary schematic diagram;

FIG. 14 illustrates a control panel window for helping to control theelectrical simulation of the circuit shown in FIG. 13;

FIG. 15 illustrates an exemplary web page listing instructions toconduct a thermal simulation;

FIGS. 16A and 16B show an exemplary web screen illustrating setup ofthermal simulation of the circuit designed according to the user'srequirements;

FIGS. 17-19 illustrate exemplary simulation status screens;

FIGS. 20A and 20B show an exemplary result of a thermal simulation;

FIGS. 21A and 21B show an exemplary web page illustrating the results ofa simulation with the changed parameters;

FIGS. 22A and 22B show an exemplary BUILD IT web page;

FIGS. 23A-23F illustrate an exemplary assembly diagram;

FIG. 24 illustrates an exemplary documentation page;

FIGS. 25A-25E illustrate an exemplary design document;

FIG. 26 shows an exemplary MYdesigns page;

FIG. 27 illustrates cropping a PCB;

FIG. 28 illustrates the allocation areas of a PCB;

FIGS. 29A and 29B illustrate exemplary PC board (PCB) layouts;

FIG. 30 illustrates a process for the interaction between thermalsimulations, electrical simulations, and PCB layout;

FIG. 31 illustrates an exemplary web page for starting the electricalsimulation process;

FIG. 32 illustrates an exemplary web page for starting the electricalsimulation process showing past electrical simulations completed;

FIG. 33 shows an exemplary web page for starting a startup analysissimulation;

FIG. 34 illustrates an exemplary web page of a startup simulationcompleted;

FIG. 35 shows an exemplary web page for selecting a different componentwithin the circuit;

FIG. 36 illustrates an exemplary web page for changing an operatingvalue within the circuit;

FIG. 37 illustrates an exemplary web page for a waveform associated withthe simulation of the circuit;

FIG. 38 shows an exemplary web page for selecting a different componentwithin the circuit;

FIG. 39 illustrates an exemplary web page for a waveform associated withthe simulation of the circuit after an alternate component has beenselected and a new electrical simulation completed;

FIG. 40 illustrates an exemplary web page for a bode plot associatedwith the simulation of the circuit;

FIG. 41 illustrates exemplary web based interface showing a schematic;

FIG. 42 illustrates moving a wire within a schematic;

FIG. 43 shows moving a component;

FIG. 44 illustrates using block symbols to represent an electricalschematic or sub circuit;

FIG. 45 shows modifying the connections between block symbols;

FIG. 46 illustrates exemplary components that may be used within aschematic;

FIG. 47 shows a power supply design with optimization control set to avalue of mid-value;

FIG. 48 illustrates a power supply design with optimization control setto a low value;

FIG. 49 shows a power supply design with optimization control set to ahigh value; and

FIG. 50 illustrates a process for placing emphasis on selectingcomponents for a design, in accordance with aspects of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

In the following detailed description of exemplary embodiments of theinvention, reference is made to the accompanied drawings, which form apart hereof, and which is shown by way of illustration, specificexemplary embodiments of which the invention may be practiced. Theseembodiments are described in sufficient detail to enable those skilledin the art to practice the invention, and it is to be understood thatother embodiments may be utilized, and other changes may be made,without departing from the spirit or scope of the present invention. Thefollowing detailed description is, therefore, not to be taken in alimiting sense, and the scope of the present invention is defined onlyby the appended claims.

The present invention is directed at enabling a user to optimize anelectrical design. A user may adjust and make tradeoffs between variousdesign goals in an electrical circuit, such as a power supply, using anInternet browser over an Internet connection. The user can quicklychange a value of a parameter using a control user interface element inorder to optimize the circuit design for their use. The user may alsochange the type of simulation run, the values of components and also thesimulation related parameters. The user can also freely change theconnectivity of the circuit as well as add and/or remove components in afree form manner.

FIG. 47 shows a power supply design with optimization control set to avalue of mid-value.

As illustrated, web based interface 4700 utilizes a conventionalinternet browser and internet connection to access an electricalschematic, in accordance with aspects of the invention. As describedbelow, the electrical design may be created over the Internet. Accordingto one embodiment, the electrical design that is created is a powersupply. Generally, power supplies are a means of taking an input voltageand current and controlling it such that the output voltage and/orcurrent is stable under different load and input conditions. Powersupplies are used in a wide variety of applications and theseapplications may have wide ranging specifications and requirements whichmay be difficult to achieve and involve the balancing of severalcompeting design goals against each other.

Interface 4700 includes optimization tuning control 4720 that isdirected at allowing a user to optimize a designed circuit by allowingthe user to easily adjust and make tradeoffs between various designgoals in a power supply design to quickly achieve the desired results.According to one embodiment, the electrical design is created usingdesign software such as the design tools described herein.

After the electrical design has been initially created, the user ispresented with a control, such as a control 4720 which in thisembodiment is illustrated as a knob. According to another embodiment,control 4720 may be presented before an initial electrical design iscreated. Control 4720 includes different settings along a scale, withone end of the scale showing optimization of the design for a parametersuch as small component footprint, and the other end showingoptimization for a parameter such as efficiency. According to otherembodiments, other parameters may be used for optimizing the circuit.For example, parameters such as thermal values, cost, power, and thelike may be used. Different settings on optimization control 4720 resultin different power supply designs and components being presented to theuser which have been optimized according to the value chosen usingoptimization control 4720. According to one embodiment, the designsinclude a bill of materials containing operating values 4710 for thedesign such as die temperature, efficiency, footprint, price, outputvoltage ripple, power dissipation of various components, phase margin,crossover frequency and transient response. In this way, the user canmake tradeoffs between the different designs to choose the best one forthe user's needs.

Control 4720 illustrates a selection of a value that is in the middle ofa range. Values in the middle range represent designs having a balanceof the parameters (foot print vs. efficiency). The closer the value isset to an end of the scale, the more heavily weighted that parameterwill be considered. If a user chooses a scale value of 1 within control4720, a design is created with a heavy emphasis on getting the smallestpossible footprint using the available components. According to oneembodiment, this may be achieved by increasing the frequency of aswitching power supply and also choosing components with the smallestfootprints which still satisfy the design requirements. Within interface4700, optimization operating values 4710 are presented to the usershowing them the operating values of the circuit. According to oneembodiment, frequency, efficiency, duty cycle, IC Pd, IC Tj, ICThetaJA,Ambient Temperature and total footprint are shown. Other values may alsobe illustrated. After the user has set control 4720 to the desiredvalue, selecting optimize circuit control 4730 optimizes the circuitaccording to the desired optimization value set using optimizationcontrol 4720.

The components used within the circuit design are illustrated in section4740 of interface 4700. For purposes of illustration, assume that theuser has selected control 4730 to optimize the circuit using a valuethat is in the middle of the range, which in this embodiment is three.

FIG. 48 shows a power supply design with the circuit designed with theoptimization control set to a value on the low end of the scale. If auser chooses a setting of 1, which is at the low end of the scale, thedesign is optimized with heavy emphasis being placed on small componentsize.

As illustrated, the optimization operating values 4810 located withinweb based interface 4700 have changed based on the selection ofoptimization control 4710. In this example, with the optimization tuningset to be at the left end of the range, the frequency has increased from581 kHz to 1003 kHz, the efficiency has changed from 82% to 80%, theduty cycle has remained constant at 17%, the IC Pd has changed from 0.49W to 0.7 W, the IC Tj has changed from 50 degrees C. to 58 degrees C.,the ICThetaJA has remained constant at 40 degrees C./W, the AmbientTemperature has remained constant at 30 degrees C., and the totalfootprint has changed from 232.2 mm squared to 179.11 mm squared. Asillustrated the efficiency value and the footprint value for thecurrently optimized circuit is shown next to control 4710. As a resultof the adjusting the optimization control some of the componentsillustrated in component section 4740 of the interface have changed. Forexample, the inductor component has changed based on the adjustment ofoptimization control 4710.

Now assume that the user selects a value of five, which is on theextreme high end of the scale and maximizes the efficiency parameter.

According to one embodiment, in the process of optimization of theelectrical design, the selection of component parts for the design isbased on an algorithm in which a target value is set for the parametersof a component. The closer a component parameter is to the target, thehigher the score for that parameter. A weight is also assigned to eachparameter of a component and the final score is the product of theinitial score and the weight (See FIG. 50 and related discussion).

FIG. 49 shows a power supply design with the circuit designed with theoptimization control set to a value on the high end of the scale.

As illustrated, the optimization operating values 4910 located withinweb based interface 4700, have changed based on the selection ofoptimization control 4710. In this example, with the optimization tuningset to be in the mid-range, the frequency has decreased from 1003 kHz to149 KHz, the efficiency has changed from 80% to 86%, the duty cycle hasremained constant at 17%, the IC Pd has changed from 0.7 W to 0.27 W,the IC Tj has changed from 58 degrees C. to 41 degrees C., the ICThetaJAhas remained constant at 40 degrees C./W, the Ambient Temperature hasremained constant at 30 degrees C., and the total footprint has changedfrom 179.11 mm squared to 953.7 mm squared. As illustrated theefficiency value and the footprint value for the currently optimizedcircuit is shown next to control 4710. In this scenario, a design iscreated with a heavy emphasis on the efficiency of the circuit.Generally, an efficient design may be created by using a low switchingfrequency in a switching power supply design, and choosing componentswhich have low resistance and low power dissipation. Although notillustrated, choosing other values using optimization control 4710places different emphasis on the parameters that are associated withoptimization control 4710. For example, if a user chooses a value of 4,a design is created with high emphasis placed on good efficiency, butstill some weighting given to small footprint. If a user chooses a valueof 2, a design is created with high emphasis placed on small footprint,but still some weighting placed on good efficiency.

FIG. 50 illustrates a process for placing emphasis on selectingcomponents for a design.

After a start operation, process 5000 moves to operation 5010 where acomponent in the design is selected for analyzing. Generally, theselection of component parts for the design is based on an algorithm inwhich a score is determined for each component that may be selected. Thecomponent with the highest score is selected.

Flowing to operation 5020, the parameters of the component beinganalyzed are determined. These parameters may include factors such as:footprint, parasitic resistance, capacitance, inductance, and the like.The closer a component parameter is to the target value based on thedesign, the higher the score for that parameter. For example, iffootprint is considered the most important parameter, then the componenthaving the smallest footprint will have the highest score for thatparameter.

Moving to operation 5030, a weight is also assigned to each parameter ofa component. For example, the weight may be based on the componentoptimization value that is set using the component optimization controlas described above.

Transitioning to operation 5040, the final score for each component isdetermined. According to one embodiment, the final score is the productof the initial score and the weight. For example, if two parameters withthe same deviation from the target have different weights, the componentwith the parameter with the higher weight receives a higher overallscore. This weighted scoring algorithm allows selection of componentstaking into account multiple parameters at once, keeping a balancebetween important characteristic factors of the component part such asfootprint, parasitic resistance, capacitance, and inductance.

Moving to operation 5050, the component having the highest score isselected for the design. For example, in selecting an optimizationsetting of 5 (See FIG. 49) to achieve high efficiency, a low target isset for the ESR (equivalent series resistance) parameter of the outputcapacitor to reduce power dissipation. A high weighting is also set forthis parameter in relation to the other parameters. Thus capacitors withlow ESR typically get higher scores than parts with high ESR which wouldgive the design improved efficiency, but the algorithm may also allowconsideration of other factors, such as the size, capacitance, price andpart availability in order to determine the overall score for thecapacitor. For example a high weight may be placed on a component beingin stock at the fulfillment warehouse, having a low price and having alow ESR. A component that is being evaluated, such as a capacitor,having a low ESR, but that is out of stock at the fulfillment warehouseand has a high price would receive a lower score than a capacitor thatis in stock, is less expensive and has a higher ESR.

The process then moves to an end operation.

FIG. 41 illustrates exemplary web based interface showing a schematic,in accordance with aspects of the invention. As illustrated in thefigure, web based interface 4100 utilizes a conventional internetbrowser and internet connection to access an electrical schematic, inaccordance with aspects of the invention.

A user can create and/or modify an electrical schematic or circuit, suchas the schematic illustrated within window 4105, by placing and movingwires and components within window 4105. The wires and components areselected by a user in order to place or move them.

According to one embodiment of the invention, the electrical schematicis drawn using vector based drawing techniques within browser window4100. As illustrated in the figure, the electrical schematic showswires, components, and feature blocks attached to a voltage regulatordevice, in accordance with aspects of the invention. The componentswithin the schematic may be moved and changed according to a user'srequirements. Feature blocks are used to represent elements orcollections of components in an electrical schematic or sub circuit. Forexample, feature block 4110 represents a current limit block. The use offeature blocks allows the user to hide the specific elements andcomponents of the block from view.

According to one embodiment, the components that are in a modifiablestate are colored, and non-modifiable components are presented in ablack and white format. Any formatting may be used to indicate whether acomponent may be modified. For example, the component may indicate thatit is modifiable by a predetermined graphic.

Scale adjustment 4115 is provided allowing the user to zoom in order toshow more or less detail. Clicking the arrows on scale adjustment 4115allows the user to incrementally change the scale of the schematicillustrated in window 4105.

Scroll bars are also provided to allow the user to scroll or pan acrossthe schematic to view areas which are not currently shown in the viewingarea.

At any point in the process, the user can conduct an electricalsimulation of the schematic they created or modified.

FIG. 42 illustrates moving a wire within a schematic, in accordance withaspects of the invention.

The user can move wires and components within the schematic shown inwindow 4105. The user may also move wires after they have been placed.The ends of wires may be moved independently from each other. In otherwords, one end of a wire may be moved while the other end stays fixed.Referring to the figure, wire 4210 has been selected and endpoint 4205has been moved. Alternatively, the user can move the entire wire atonce. For example, instead of moving just endpoint 4205, wire 4210 maybe moved as an entire wire (not shown).

According to one embodiment, the user can specify a minimum allowedmovement increment or grid so that it is easier to make the ends oflines meet or lines to connect to components. Grid 4215 illustrates oneexemplary grid that may be used. The grid may be sized in many differentways. For example, the grid may change size when the scale of thedrawing changes.

When user moves a wire or component onto a grid point, a check is madeto see if the moved end of the component or wire overlaps the end (ormidpoint) of another wire within the tolerance of the grid increment. Ifit does, an algorithm determines the logical connectivity of the changedschematic and determines the netlist or component connectivity listbased on the change. The netlist or component connectivity list may beused to generate a simulation. According to one embodiment, the netlistis determined on the client (user) side rather than sending it to theserver. Determining the netlist on the client side helps to increasesthe level of interactivity of the application. Alternatively, thecoordinates of the lines and the components may be sent to the serverside of the application to determine the connectivity/netlist.

FIG. 43 shows moving a component, in accordance with aspects of theinvention.

Referring to the figure, component 4220 has been selected and removedfrom between wire 4305 and wire 4310. Component 4220 is now coupled towire 4210. If the user desires, wires 4305 and 4310 may be removed ormoved to some other location. Additionally, any other component withinwindow 4105 may be moved or removed.

FIG. 44 illustrates using block symbols to represent an electricalschematic or sub circuit, in accordance with aspects of the invention.

The user can use a predefined block symbol to represent an electricalschematic or sub circuit within the schematic. Alternatively, the usercan create a new block symbol to represent an electrical schematic orsub circuit. According to one embodiment, the components and blocks maybe selected by the user from a palette of choices. As illustrated, fourblock symbols are used to illustrate the schematic. The user may stillmake modifications to the schematic when using block symbols. Forexample, the user may select wire 4415 that is coupled to block symbol4410 and 4420 and connect wire 4415 to another location if desired.

Block symbols may also be used depending on the level of detail the userdesires to view. For example, information box 4405 illustrates the useris viewing level 0. The user may switch to another level by clicking onthe level control (above the zoom control in FIG. 45.) When the userviews level 1 more detail may be shown. The user may control the levelof detail shown.

FIG. 45 shows modifying the connections between block symbols, inaccordance with aspects of the invention. The user may modify theschematic by adding block symbols or changing the connection of wiresbetween the block symbols. The user can also insert electricalcomponents into the block diagram.

As illustrated in the figure, the user has moved block 4410 anddisconnected the feedback connection from block 4410 to block 4515. Theuser has also modified the wire from Vout on block 4410 to the Voutbetween block 4420 and block 4515. As a result of the modification wire4510 meets wire 4415 at a ninety degree angle.

The user can conduct an electrical simulation of the block diagram theycreated or modified by pressing the start new simulation button on theweb page. Once the simulation is finished the user may view the resultsby pressing the view results button on the web page. The electricalcircuit or block diagram may also be saved and recalled it a later timefor editing or simulation.

According to one embodiment, a database is used to store the user'scircuit information. Circuits and sub circuits are stored in ahierarchical and independent manner in the database. This enables thecircuit information to be stored in a way which is more conducive tousing a block diagram approach.

The circuit blocks stored in the database can be assembled based on theuser's design requirements to create an optimal circuit for the user.For example, if the user has a high load current design requirement,this may show a need for an RC snubber circuit on the switch node of aswitching regulator, and a block may be added into the circuit andpresented to the user.

Certain features of a device may require blocks to support the feature.The circuit information about the block is stored in the database andadded to the circuit when required. For example, the LM2679 voltageregulator device produced by National Semiconductor Corporation has acurrent limit feature which requires that a current limit resistor beconnected between the current limit pin of the IC and ground. Thiscurrent limit resistor can be represented by a block in the database andit can be added to the user's circuit when an LM2679 is selected. If adevice is selected which does not require a block, the block is notadded to the user's circuit. For example, the LM2678 does not require acurrent limit block and it is therefore not added to the circuit. Thisallows a template circuit to be used as a basis for constructing morecomplex circuits.

FIG. 46 illustrates exemplary components that may be used within aschematic, in accordance with aspects of the invention. The user canplace components or wires from a palette of available options or selectplacement options from a drop down menu.

As illustrated in the figure, six components are included within palette4605 and are used in accordance with one embodiment of the invention. Awire component, two simulation components, and three electricalcomponents are provided. Any number of components may be provided. Forexample, the number of components provided may change with the circuitbeing designed.

The user selects one of the components by clicking on the componentwithin the web page. Once the component is selected it may be moved to apoint within the schematic as chosen by the user. For example, circuit4610 could have been created by placing components from palette 4605.

FIG. 5 shows an overview flow diagram illustrating general steps of themodifying or creating a schematic, according to aspects of theinvention. After a start block, the logical flow moves to a block 510where the schematic is displayed to the user through a web page over astandard Internet connection. Moving to block 520, the user chooses acomponent that they desire to modify or add. Transitioning to block 530,the component is added or modified. Flowing to block 540 the schematicmay be analyzed. According to one embodiment, the design is analyzedusing an electrical simulation. The design may also be analyzed using athermal simulation tool, an electrical simulation tool, and a PCB layouttool. The interaction between the tools allows the user to visualize andobtain the thermal and electrical behavior of the design. Stepping to ablock 550, the circuit may be ordered and built. A part, a kit of parts,or an evaluation board may be ordered from a supplier.

According to one embodiment of the invention, a system is provided bywhich users, with no or little special client-side software, and littleor no knowledge of available circuit components, can easily andefficiently create, modify, and simulate, and order circuits andcomponents that satisfy their functional requirements. According to oneembodiment of the invention, the user is presented with a series of webpages to achieve this result.

FIG. 30 shows the process for interaction between the thermal simulationtool, the electrical simulation tool, and the PCB layout, in accordancewith aspects of the invention. The process illustrated in FIG. 30 may beperformed in any order and repeated as many times as needed to convergeupon a design that satisfies the user's requirements. A commonenvironment to perform electrical and thermal simulations successivelyallows the user to interactively design a circuit. For example, when theuser changes a component in the electrical simulation, that change isalso reflected in the thermal simulation. When the user changes acomponent in the thermal simulation this change is reflected in thethermal simulation.

After a start block, the logic flows to block 3010, at which point theadjustment of the PCB layout of the components is performed. Generally,the components are placed in predetermined landing areas on the PCBbased on their use. The user may also adjust properties relating to thePCB. For example, the user may crop the PCB.

Stepping to block 3020, a thermal simulation of the design is performed.The thermal simulator uses validated thermal models for the componentsand the reference PCB. According to one embodiment of the invention, theoutput of the thermal simulation is a color plot of the PC board underthe design's steady state electrical load conditions.

Transitioning to block 3030, the process performs an electricalsimulation of the circuit. The electrical simulation is run on thecomponents currently chosen for the design and provides the user withaccurate performance information. The user may also edit component,supply, and load values to refine their design.

Moving to decision block 3040, the process determines whether to adjustthe PCB layout of the circuit. When the layout is to be adjusted, theprocess returns to block 3010 where properties relating to the PCBlayout may be modified. When the layout is not to be adjusted, theprocess moves to decision block 3050, at which point the processdetermines whether to run another thermal simulation. If another thermalsimulation is to be performed, the process returns to block 3020 andperforms another thermal simulation. If a thermal simulation is not tobe performed, the process steps to decision block 3060 at which pointthe process determines whether to run another electrical simulation. Ifso, the process returns to block 3030 and performs another electricalsimulation. If not, the process moves to an end block and terminates.The electrical simulation results that affect the thermal simulation mayalso be carried into the thermal simulation. For example, the duty cycleof the IC affects the power dissipated in the IC that affects thetemperature in the thermal simulation. In a similar way, the temperatureof the IC affects the switch resistance of the IC, which affects theelectrical behavior. Similarly, changing the PC board layout may affectthe thermal and electrical properties of the circuit. The interactionbetween the thermal, electrical and PCB layout parameters may beadjusted by running successive simulations until the results converge toa predetermined level. The predetermined level is based on the user'sspecifications.

FIG. 4 shows a block diagram that gives an overview of functionalmodules 234 used to implement the techniques described. Functionalmodules 234 (FIG. 2) include numerous functional modules. Referring toFIG. 4, in the illustrated embodiment, the modules 400 includerequirements form module 410, component determination module 412,circuit design module 414, schematic design generation module 416, PCboard layout module 418, electrical simulation module 420, thermalsimulation module 422, component acquisition module 424, and schematicmodification module 426. The functions of each of these modules aredescribed in more detail within this specification.

FIG. 6 illustrates an exemplary web page for starting the process fordesigning a circuit. The web page illustrated contains text 610 thatexplains the four general steps of the process to the user, and containslinks to web pages for “Choose a Part” 620, “Create a Design” 630,“Analyze a Design” 640, and “Build It” 650 that contain more informationrelating to the four general steps. The page contains links to theuser's recent designs 660, a “MyDesigns” link 670 to all of the user'sdesigns, as well as a link to electrical simulations 680, thermalsimulations 690, and the user's “BuildIt” orders 695.

When the user desires to start the process the user may select the STARTHERE link 605. It should be noted that many of the links and buttons “toweb pages” are actually links that result in the execution of softwaremodules which produce, as output, the web pages that are delivered tothe user. Selecting START HERE link 605 directs the user to the web pageas illustrated in FIG. 7.

Suggesting Components Based on User-Specified Requirements

For the purpose of explanation only, it shall be assumed that a userdesires to create a power supply. Accordingly, the user selects STARTHERE LINK 605 shown in FIG. 6. While the techniques described hereinshall be described in the context of designing, simulating, and orderingparts for a power supply circuit, the techniques are not limited to anyparticular type of circuit.

According to one embodiment, a web server, such as web server 200 (FIG.2) responds to selection of START HERE link 605 by invoking therequirements form module 410. The requirements form module 410 providesone or more “requirements” web pages to client computer 300. Therequirements web pages allow the user of the client to specifyrequirements for a circuit.

FIG. 7 shows an exemplary requirements web page for receiving therequirement information from a user for a power supply circuit. Theillustrated requirements page includes user interface controls forspecifying minimum and maximum input voltages (controls 702), and outputvoltage and current (controls 704). The requirements web page furtherincludes controls 706 for additional requirements, such as whether thecircuit requires an ON/OFF pin, an Error Flag, Sync Pin, or multipleoutput voltages and currents. Other requirements that may apply to apower circuit, for example, may include requirements associated withambient temperature, efficiency, frequency, and the like. It should benoted that the specific user interface controls presented by therequirements web pages will vary from implementation to implementationbased on a variety of factors, including the type of circuit for whichthe requirements are being specified.

The requirements information entered by the user into the requirementsweb page may be transmitted back to the web server. The operation ofsending the requirements information to the server may be initiated, forexample, by the user selecting a particular control, such as button 708,on the requirements web page.

Based on the requirements information, a component determination module412 determines the components that could be used to build a circuit thatwould satisfy the specified requirements, and generates one or more“suggested component” web pages. The process of determining thecomponents that could satisfy the specified requirements may beimplemented, for example, by applying filters to component data storedin a database. The filters may, for example, compare the valuesspecified in the “output voltage” and “output current” fields of therequirements web page against values in corresponding columns of a“component” table in a database.

The process may also involve using values from the requirementsinformation as input into formulas, where the output of the formulas isused to determine which components could satisfy the specifiedrequirements. For example, assume that the user desires a boostregulator circuit. Integrated circuits used in boost regulators have aswitch current rating. The switch current rating of each integratedcircuit that can be used in a boost regulator may be stored in therecord for that integrated circuit in a database. To determine whichintegrated circuit may be used, the input voltage, output voltage andoutput current specified in the requirements information are used tocalculate a required switch current rating, and the required switchcurrent rating is compared against the switch current ratings in thedatabase to select those integrated circuits within the database thatcan satisfy the specified requirements.

FIGS. 8A and 8B are an example of a suggested component web pagegenerated in response to the requirements specified according to FIG. 7.In the present example, the suggested components fall into twocategories: switching regulators for use in a Buck Topology, andswitching regulators for use in a Flyback Topology. An understanding ofthe distinction between these categories of switching regulators is notimportant for the purpose of understanding the techniques describedherein. However, such distinctions may be relevant to the user designingthe power circuit. Therefore, component determination module 412generates the suggested component web page in a manner that groups thesuggested components into those and any other applicable categories.

Component determination module 412 further includes in the suggestedcomponent web page other information relevant to the user's selection ofa component. In the illustrated embodiment, the other informationincludes the maximum current, the typical efficiency, whether thecomponent has an ON/OFF pin or an Error pin, a field for “otherfeatures”, the frequency of the component and an estimated price of thecomponent. Other information may be included in the display. Forexample, the number of components in stock and the physical size of thecomponents may be displayed. Additionally, a diagram of the componentmay be shown.

In the illustrated implementation, the names of the suggested componentsare presented in the form of links. Selection of the link associatedwith a component results in the delivery of a “product folder”.According to one embodiment of the invention, the product folder is aweb page that presents detailed information about a component. Forexample, selecting link 802 associated with the LM2679-ADJ componentproduces the product folder web page as shown in FIG. 9. The informationand controls contained on the product folder web page of a componentshall be described in greater detail hereafter.

The information contained in the suggested component web pages, and theproduct folders of the components listed in the suggested component webpages, satisfies only part of the users needs. In particular, the useris interested in creating an entire circuit that satisfies the specifiedrequirements, and not merely in identifying a component that could beused in such a circuit. Therefore, according to one embodiment of theinvention, the user is presented with a control for automaticallygenerating the design of such a circuit using a component selected fromthe suggested component web pages.

A thermally enabled indicator 806 is displayed for those parts that arethermally enabled. This allows the user to quickly identify parts thatmay be simulated using the thermal simulation tool. A build it indicator808 is displayed for those parts that may be purchased in a custom kit.In addition to the information currently displayed, other informationmay be displayed. For example, the total bill of materials (ROM) pricemay be displayed. This may be useful information to help the user decidewhich part to select. According to one embodiment of the invention, whenthe part is not thermally enabled, the user may supply the thermalrequirements data for the component so that the component may bemodeled.

Automatic Circuit Design

Referring again to FIGS. 8A and 8B, the listing for each componentincludes a field that contains a CREATE DESIGN button, such as CREATEDESIGN BUTTON 804, which, when selected, causes the automatic generationof a circuit design that uses the selected component, and satisfies thespecified requirements that were initially entered by the user. Forexample, assume that the user determines, based on the informationcontained on the suggested components web page and, optionally, the moredetailed information on product folder web pages, that the LM2679-ADJcomponent is the best of the suggested components for the user'spurpose. The user may then select CREATE DESIGN BUTTON 804 associatedwith that component to cause generation of a power circuit that uses theLM2679-ADJ component, and satisfies the requirements specified on therequirements web page shown on FIG. 7.

According to one embodiment, selection of a create design button causesa message that indicates the requirement information and identifies theselected component to be sent to a circuit design module 414. Inresponse, circuit design module 414 designs a circuit that uses theselected component and satisfies the specified requirements.Specifically, circuit design module 414 determines components that areutilized in the circuit in addition to the selected component, and howthose components should be arranged to create the circuit (the circuit“topology”).

The circuit may contain many more components in addition to the selectedIC component. Rules and mathematical formulas are used to select theoptimal values for these additional components. These rules may be setup to optimize certain design criteria over another. For example, if theuser desires to have minimal output voltage ripple, a larger outputcapacitor value may be chosen, but this may degrade the circuit'sability to respond to a sudden change in input voltage (transientresponse). Thus, the user may be given a choice to emphasize one designcriteria over another.

One output of circuit design module 414 is a set of rules for theadditional components in the circuit. For example, for a certain designthe output capacitor must have a capacitance greater than or equal to100 μF and an equivalent series resistance of less than or equal to 100mΩ. These rules are used to select alternate components if desired.

Various techniques may be used by circuit design module 414 to determinethe topology of the circuit. For example, numerous topology “templates”may be stored on the server-side at a location accessible to circuitdesign module 414. Data may also be stored that associates general typesof circuits with one or more of the topology templates. In an embodimentof the invention that uses topology templates, circuit design module 414selects the topology template based on the type of circuit that is beingdesigned, and then uses the selected topology template, the selectedsuggested component, and the requirements information to determine theother components required for the circuit.

According to one embodiment, circuit design module 414 transmits back tothe user one or more components list web pages. The components list webpages identify the components that are included in the circuit designedby circuit design module 414 (referred to herein collectively as the“designed circuit components”). The designed circuit components thusinclude the selected component and the additional components determinedby circuit design module 414.

For the purpose of illustration, it shall be assumed that the userselects the create design button associated with the LM2679-ADJcomponent.

Product Folder Web Pages

FIG. 9 shows an exemplary web page illustrating a product folder webpage for the LM2679-ADJ component. In the illustrated embodiment, theproduct folder web page includes links 902 to related informationrelating to the component, including a General Description section, aFeatures section, an Applications section, a Datasheet section, aPackage Availability, Models, Samples & Pricing section, and a designtools section. A parametric table 904 showing the operating parametersof the component is also displayed.

The General Description section includes a general description of thecomponent. The Features section lists the features of the component. TheApplications section lists applications in which the component istypically used. The Datasheet section contains links to view online ordownload the data sheets for the component.

The Package Availability, Models, Samples & Pricing section listspackage types and other options available for the component, indicatesthe status, availability and price of the component for each option, andcontains controls which, when selected initiate an operation for placingan order or sample for each option for the component.

The Design Tools section includes a link (not shown) to view online ordownload information about software tools that may be used to assist indesigning circuits that use the component. Button 905 allows the user togo directly to WEBENCH if they got to the product folder first beforeentering WEBENCH.

Bill of Materials

FIGS. 10A and 10B illustrate an exemplary bill of materials web pagethat indicates the components used in the circuit design generated bycircuit design module 414. In addition to the selected LM2679-ADJcomponent, the bill of materials web page lists numerous other circuitcomponents from a variety of manufacturers. If the user desires tosubstitute any of the designed circuit components listed in the bill ofmaterials page for another component, the user may select the “selectalternate part” button associated with that component. In response toselection of the “select alternate part” button associated with acomponent, the user is presented with a list of alternate components.Such substitutions may be desirable, for example, if the user desirescomponents from a particular manufacturer. For example, suppose the userdesires to select an alternate component for component part D1, the userselects button 1002. The alternate components for component part D1 arethen displayed to the user (See FIGS. 11A and 11B and relateddiscussion).

The bill of materials page provides user interface controls 1004allowing the user to edit the information stored about your simulation.All changes are stored automatically and associated with the user. Fileoperation copy allows the user to create an identical design, which canthen be altered for comparison. File operation rename allows the user tochange the label on the current design. File operation add allows theuser to add or edit notes stored with the design. File operation printallows the user to print a report of the design. XML file operationallows XML to be displayed. A web browser capable of displaying XML suchas Internet Explorer 5.0, is used for this feature. Share this designfile operation allows the design to be shared among colleagues. Forexample, the design engineer could share the design with other designersor with their supervisor.

A scale drawing of the top view of the components in the design isdisplayed if available. According to one embodiment, these drawingoutlines are stored in a database on a web server. The drawings are in acolor scheme similar to the actual colors of the components. Thisdisplay allows the user to see the size of the components, which isoften an important attribute to consider when creating a circuit design.If the component cannot be thermally simulated, the letter N isdisplayed instead of the scale drawing of the top view of the component.This allows the user to readily determine whether a component may bethermally simulated. In addition to the information shown, otherinformation may be included. For example, the number of components instock, the price, and the like may be shown.

Alternate Components

FIGS. 11A and 11B illustrate an exemplary web page showing alternatecomponents for a component. The user may select from a list of suppliedalternate components or enter a custom component. Along with thealternate components, other information relating to the component isdisplayed to the user. For example, for the D1 component, the forwardvoltage drop, max rated current, max voltage rating, physical dimensionsof the component, price, quantity available, as well as if the componentis thermally modeled is displayed. The top view scaled drawing ofthermally simulated components is shown. There is also an indicator (theletter N) to show if the alternate component cannot be thermallysimulated. These features allow the user to view the size of alternatecomponents and choose parts that may be simulated using the thermalsimulator if so desired. On the alternate components screen, the user isallowed to manually enter the values for a component if desired.According to one embodiment of the invention, to allow a component to bethermally simulated, the user is given the option to enter simulationparameters including the x, y and z dimensions of the component, thepackage type of the component and a choice of a top view drawing to beused for the component.

The recommended limits for the important parameters for the componentare displayed (1108, 1110, and 1112). These are determined by componentdetermination module 412. This allows the user to better select analternate component or enter custom values. As will be appreciated,other information may also be displayed to the user. According to oneembodiment of the invention, when the user enters a custom component,the component cannot be thermally simulated. According to anotherembodiment of the invention, the user may enter the thermal parametersneeded to simulate the component. According to this particular example,the user has selected alternate component 5 to replace component D1shown in FIGS. 10A and 10B. Once the user has selected an alternatecomponent, the user selects Update BOM button 1102 to incorporate thecomponent into the design.

Referring again to FIGS. 10A and 10B, once the user has made any desiredcomponent substitutions, the user may select operating values control1006 to obtain operating value information for the circuit created bycircuit design module 414 using the parts listed in component listspage. FIGS. 12A and 12B illustrate exemplary web pages showing theoperating parameters for the circuit associated with the bill ofmaterials of FIGS. 10A and 10B including the changed D1 component. Fromeither the components list web page or the operating values web page,the user may select “schematic” control 1008 to cause a schematicdiagram of the circuit to be generated.

In response to selection of schematic control 1008, one or more messagesidentifying the designed circuit components, as well as the topologydata for the generated circuit, are sent to a schematic diagramgeneration module 416. The schematic diagram generation module 416generates one or more web pages that include a schematic diagram of thecircuit, and delivers the schematic web pages to the user.

Operating Values

FIGS. 12A and 12B show exemplary web pages illustrating operating valuesof a circuit. The operating values provide the user with the results ofcalculations for the power supply design. These calculations may then beused in the selection of the design components, and are reported to givethe user an estimate of the circuit performance. According to oneembodiment of the invention, the operating values are updated when theuser changes the components. For example, when the user selects analternate component the operating values change. Referring to FIGS. 12Aand 12B, the operating values provide the Pulse Width Modulationfrequency, continuous or discontinuous conduction mode, and total outputpower. The operating values also provide the user with a currentanalysis, power dissipation analysis, and a description of severalvalues at the operating voltage and current of the circuit. The user canalso enter a different value for the operating voltage and operatingcurrent then recalculate the operating values based on these inputs.

Schematic Diagram Generation

Referring to FIG. 13, an exemplary schematic diagram web page isillustrated that may be generated and delivered to a user in response touser selection of schematic button 1008, or by clicking link 1012, or byselecting button 1014 which goes to another page that allows access tothe to the electrical simulator. (See FIGS. 10A and 10B). The schematicdiagram includes the components identified in the components list pagearranged in a circuit that satisfies the requirements specified by theuser. According to one embodiment, the schematic diagram generationmodule 416 used to generate the schematic web pages is the WEBENCHElectrical Simulator. While the illustrated embodiment uses the WEBENCHElectrical Simulator module for generating schematic diagram web pages,the present invention is not limited to any particular schematic diagramgeneration module 416. Any module capable of generating a schematicdiagram based on a list of components and schematic information may beused.

Electrical Simulation

FIG. 31 illustrates an exemplary web page for starting the electricalsimulation process. Selecting the simulate link starts the simulationprocess. When there have been other electrical simulations performed onthe circuit a list is placed under the simulate start link.

FIG. 32 illustrates an exemplary web page for starting the electricalsimulation process showing past electrical simulations completed. As canbe seen by referring to the figure, two other simulations have beenperformed on the circuit. Past simulation table 3210 includes asimulation number, a simulation ID, the date of the simulation, and anynotes or description for the simulation. When the user desires toreference a past simulation, the user selects one of the simulation IDlinks.

FIG. 14 illustrates a control panel window for helping to control theelectrical simulation of the circuit shown in FIG. 13. The user mayselect various analysis methods, start frequency, stop frequency, andthe like. The user may also create bode plots of the analysis.

According to one embodiment of the invention, the user may select LoopGain Measurement analysis, Line Transient Response analysis, LoadTransient Response analysis, Steady State simulation analysis, andstartup analysis of the circuit by selecting an analysis from drop downselection menu 1410. The user may also enter values into input boxes.The input boxes change depending on the analysis selected. For example,when the selected analysis is loop gain measurement the user may enter astart frequency value, and a stop frequency value. When the user isready to perform the electrical simulation the user selects the simulatebutton.

FIG. 33 shows an exemplary web page for starting a startup analysissimulation, according to an embodiment of the invention. As illustratedin the figure, WebSIM control panel 3320 illustrates a startupsimulation running for a simulation time of 5 milliseconds. Whenperforming a startup analysis the user may enter a new simulation timeinto the simulation time input box. To start the simulation the userselects the simulate button.

FIG. 34 illustrates an exemplary web page of a startup simulationcompleted. As shown in the figure, the simulation includes a WebSIMSimulation log window that informs the user when the simulation iscompleted. The simulation is typically completed within a few seconds.

Once an electrical simulation is run, the user may click on voltage orcurrent probe symbols to view waveforms. A current probe allows the userto view the current through a component in the design. The voltage probeallows the user to view the voltage with respect to ground.

FIG. 35 shows an exemplary web page for selecting a different componentwithin the circuit in accordance with aspects of the invention. Thesimulation tool allows the user to select alternate components withinthe circuit and change operating values. According to one embodiment ofthe invention, the user selects the component to adjust or change itsproperties. According to the present example, the user has selected theCout component within the schematic. In response to the selection, theSelect a part for Cout window appears listing various components thatthe user may choose from. The user may also enter custom values andinclude a reference part number to keep track of the custom part.

FIG. 36 illustrates an exemplary web page for changing an operatingvalue within the circuit, according to an embodiment of the invention.The operating values may be changed by selecting the node or componentwithin the schematic diagram. According to the present example, the userhas selected Vin. In response to the selection of Vin the Enter Valuesfor Vin window appears. The user may enter the final voltage as well asthe pulse rise time.

FIG. 37 illustrates an exemplary web page for probing a waveformassociated with the simulation of the circuit, in accordance withaspects of the invention. In response to selecting the V_OUT node afteran electrical simulation has been run, the Probe V_OUT window appears.The graph updates if a component or value is changed. In this particularcase, with an input voltage step of 0V to 20V in 50 μs, V_OUT rises tothe target value of 5V in about 1.2 milliseconds with a bit ofovershoot. The SetM1 and SetM2 buttons may be used create measurementbars within the waveform graph.

FIG. 38 shows an exemplary web page for selecting a different componentwithin the circuit to adjust the rise time of the circuit according toan embodiment of the invention. The rise time can be controlled byadjusting soft start capacitor Css within the circuit. In response toselecting the Css component the Select a part for Css window appears.The select window shows alternative parts that may be selected.According to the present example, the user has selected the secondcapacitor changing the capacitance from 0.0039 to 0.0047. The user thenruns another simulation to determine what effect changing the Csscomponent has on rise time.

FIG. 39 illustrates an exemplary web page for a waveform associated withthe simulation of the circuit after an alternate component has beenselected and a new electrical simulation completed. In response toselecting the V_OUT node after the simulation has been completed theProbe V_OUT window appears. As can be seen by referring to the figure,the rise time has increased to about 1.5 milliseconds. The user maycontinue to change parameters or components until their specificationshave been met.

FIG. 40 illustrates an exemplary web page for a bode plot associatedwith the simulation of the circuit, in accordance with aspects of theinvention. According to the present example, a user has selected theBode Plot button to view a Magnitude and Phase Bode Plot. In response tothe selection of the Bode Plot button the Probe BODE_PLOTS windowappears. The user is provided with graphical waveforms illustrating themagnitude and phase as well as values displayed as text at variouspoints within the graph. According to one embodiment, the magnitude andphase at the M1 and M2 marker is provided. The frequency at magnitudezero, the gain margin, and the phase margin is also provided.

At any point during the simulation process the user may select thethermal simulation link on any of the exemplary web pages to perform athermal simulation of the circuit. Similarly, when within a thermalsimulation, the user may select the electrical simulation button toperform an electrical simulation.

Thermal Simulation

The user may select a control from one of the previous exemplary webpages to create a thermal simulation. For example, the user may selectlink 1010 (FIG. 10A) or button 1014 (FIG. 10A), which takes the user toanother page that allows selection of the thermal simulator. The usermay elect to perform a thermal simulation at any time during the processafter the user has chosen the components for the circuit.

Referring to FIG. 15, an exemplary web page is displayed which listsinstructions to conduct the thermal simulation. The web page includes alist with links 1510 to any previous thermal simulations that have beenperformed for the current design. Link 1520 provides access to allthermal simulations conducted by the user for all designs. To start anew thermal simulation of the circuit the user selects the Start a newWEBTHERM simulation link 1530. Selecting link 1530 directs thermalsimulation module 422 to display a thermal simulation setup web page.

FIGS. 16A and 16B show an exemplary web screen illustrating setup ofthermal simulation of the circuit designed according to the user'srequirements. The thermal simulation helps the user to identify heatproblems on the printed circuit board early on in the design process andcorrect the issues before the board goes into production. This can savea lot of time and avoid costly quality accidents.

Briefly described, the thermal tool simulates the thermal behavior of anelectronic printed circuit board having components. The thermalsimulator uses validated thermal models for the components and thereference PCB. According to one embodiment of the invention, thermalsimulation module 422 used to conduct the thermal simulations isWebTHERM module provided by Flomerics, Inc. The user defines theenvironment, and the problem is solved using the thermal simulator'sconduction, radiation and convection solver. According to one embodimentof the invention, the output of the thermal simulation is a color plotof the PC board under the design's steady state electrical loadconditions. No special hardware is required to run the thermalsimulation. Instead, the user views the thermal simulation in the webbrowser. Designers may seamlessly qualify their designs from a thermaland electrical standpoint. Integration of these tasks over a network isa major improvement in design accuracy and can save a significant amountof time in the design cycle.

When the new simulation button (link 1530 as shown in FIG. 15) isselected, a screen appears with a drawing of the printed circuit boardlayout 1610 for the design, and areas that allow the user to specifyoptions for thermal simulation. A picture of the physical layout of thePC board appears in the user's web browser, showing the placement ofeach component and the copper routing. There are controls for adjustingcharacteristics for the thermal simulation, including controls for theboard orientation, edge temperature and airflow direction and speed,copper thickness, operating input voltage and operating output current,and board orientation, which allow the user to adjust parameters for thesimulation.

Printed circuit board display 1610 consists of copper interconnect lines1615 and top view drawings 1620 of the various components for the designwhich are placed in the appropriate positions on PCB 1625. Thesecomponents may include parts from many different sources. According toother embodiments, the board and components may be displayeddifferently. For example, a three-dimensional representation of theboard may be displayed to the user.

According to another embodiment of the invention, the user may specifyalternate locations for the components on the PCB or alternate copperinterconnect lines or routing of the lines. Additionally, the user mayclick on a select alternate components button for a given componentdirectly from the screen. The user may then select alternate componentsto replace the selected component or obtain additional information aboutthese components. The user could also manually enter the component'svalues in a custom component input box.

According to another embodiment, the user may move the components on thePCB. According to one embodiment, the user is limited to moving thecomponents within specified regions of the PCB to help ensure assurethat the electrical connections are maintained. This allows the user tomove the components farther apart or closer together which is animportant factor affecting the temperature of the board and components.

According to yet another embodiment, the user may change the locationand size of the copper areas on the board by clicking on a copper shape,which brings up controls to change the size and/or move the coppershape. Changing the copper area on the board affects the thermalcharacteristics of the design.

Referring to FIGS. 16A and 16B, temperature characteristics of thecircuit may be specified by the user. For example, the edge temperatureof the board may be specified as insulated or a specific temperature.These characteristics are specified in input boxes 1630, 1635, 1640, and1645 adjacent to the corresponding edges of PCB 1625. The input boxeshave a check box to specify insulated and another input box that allowsthe user to enter the edge temperature. According to one embodiment,when the user checks insulated, the edge temperature changes to N/A ordims out. If the user enters a specific temperature, the insulated checkbox is automatically unchecked.

Controls 1650 allow the user to specify the ambient temperature aroundthe top (component) side and bottom side of the board. Controls (notshown) may be provided to specify the ambient temperature at differentlocations of the board. Airflow controls 1655 allow the speed anddirection of the airflow to be specified. According to one embodiment,the direction of airflow is specified by clicking on a radio button inan array of radio buttons surrounding a picture of a board. The radiobutton clicked specifies which side of the board the airflow comes from.According to one embodiment, the airflow may be adjusted to come fromany point, or points, from around the board.

Simulation ID input box 1660 allows the user to enter a text name forthe simulation. The user may also enter comments about the simulation incomments input box 1665.

Control 1680 allows the user to change the copper weight of the board.

After entering the desired parameters for simulation, the user submitsthe simulation job to thermal simulation module 422 by selecting submitbutton 1670. A status screen then appears to allow the user to check thesimulation progress. A simulation typically takes two to three minutesto complete, excluding queue time. This time varies according to manydifferent factors, including: complexity of simulation, demand onserver, network conditions, and the like.

FIGS. 17-19 illustrate exemplary simulation status screens. After theuser submits the simulation, the simulation status screen appears. Thestatus of all the simulations is indicated in a table along with thetime at which that status began. The status is “queued” (See FIG. 17),“processing” (See FIG. 18) or “completed” (See FIG. 19). At any pointduring the simulation, the user may select refresh button 1710 to updatethe status of the simulation. When a simulation is completed, the usermay click on the appropriate simulation link in the table to view theresults. After the simulation is complete, the user can view the result,a full color plot of the temperature across the board (See FIG. 19 andrelated discussion). The temperature of each component is also listed inan accompanying table. If desired, the user can adjust parameters andresubmit the job for simulation.

FIGS. 20A and 20B show an exemplary result of a thermal simulation. Thesimulation results image 2010 shows outlines of the PCB copperinterconnect and components and is labeled with the names ofinterconnect traces and component names. Superimposed on top of the PCBcopper interconnect and components is a color plot of the temperaturesacross the board. The color of a specific region indicates thetemperature of that region. For example, variations of red may indicatehotter temperatures, while variations of blue may indicate coldertemperatures. Many coloring schemes may be chosen to indicatetemperature differences. All that is required is that the user be ableto differentiate between areas on the board that are above a user'sdesired operating temperatures. According to one embodiment of theinvention, the user may select the range of temperature to view. Forsome parts, the top surface temperature is plotted. For instance, thetemperature of the top surface for passive components and the board isplotted. The temperature of an internal part, such as the die, of eachcomponent may also be plotted, since this temperature is usually thehottest part of the component. This temperature may be represented by asquare or rectangle plotted within the component. The size of thissquare or rectangle does not have to be to scale if it is desired toconceal the die size or other internal part from the user. A scale 2020next to the plot indicates the temperatures corresponding to the colors.As will be appreciated by those of ordinary skill in the art in view ofthe present disclosure, other surfaces of the components may be plotted.For example, a three-dimensional plot of the PCB board and componentsmay be shown.

The names of each component and the numeric temperatures of eachcomponent are indicated in table 2030. The temperatures of the componentmay be the maximum temperature or other critical temperature such as thedie temperature. The user is given the option to rescale the maximum andminimum temperatures represented in the plot of the results. This isspecified in entry boxes 2040 that allow the user to enter the minimumand maximum temperatures. According to one embodiment, the user clickson a link to initiate the resealing process. The resealing may alsoautomatically be done after entering a new value into entry boxes 2040.It will be appreciated by those of ordinary skill in the art, in lightof the present disclosure, that the same simulation parameter displaysare shown on this screen as were shown on the initial simulation launchscreen. This allows the user to review the parameter values that wereused in the simulation. The user may also change the parameter valuesand launch a new simulation from this screen. For example, suppose theuser determines that the IC should only reach a maximum temperature of130 degrees centigrade. Accordingly, the user may determine that a fanis required for the design. Suppose the user desires a fan having avelocity of 400 LFM coming from the edge closest to the IC. The userselects submit button 2050 which calls up a screen (FIGS. 16A and 16B)which allows the user to enter changes and run a new thermal simulationwith the changed parameters.

FIGS. 21A and 21B show an exemplary web page illustrating the results ofthe thermal simulation with the changed parameters. As can be seen byreferring to FIG. 21A, the temperature of the D1-diode has dropped from188° C. without a fan to 128° C. with the use of a fan. Once the user issatisfied with the thermal and electrical properties of the circuit, theuser may order the components or kit to construct the circuit.

PCB Layout

FIG. 27 illustrates cropping a PCB in accordance with aspects of theinvention. As shown in the figure, cropped PCB 2700 includes circuitboard 2705, width controls 2710, height controls 2715, deleted widtharea 2720, and deleted height area 2725. The PC board layout is createdfor the user by printed circuit board layout module 418 (See FIG. 4 andrelated discussion). The appropriate layout is selected based oncritical parameters. For example, the parameters may include: thetopology of the circuit, the IC selected, the size of the selectedcomponents, whether the design requires a large amount of copper todissipate heat or a heat sink to dissipate heat, and the like.

The user may define the size of the boards by adjusting controls 2710,and 2715. By adjusting the controls, the user may remove the unnecessarycopper areas from the PC board. According to one embodiment of theinvention, the user may perform a thermal simulation of the board basedon the newly defined board size.

Width controls 2710 may be positioned to delete a portion of the widthof the board. The width may be adjusted manually by the user orautomatically. The user may adjust the width of the PCB by selectingwidth controls 2710 and sliding the controls to a desired width.According to the present example, width controls 2710 have been moved todelete width area 2720.

Similarly, height controls 2715 may be positioned to delete a portion ofthe height of the board. As shown, height controls 2715 have beenadjusted to delete height area 2725. A user may adjust the height of thePCB by selecting height controls 2715 and positioning the controls toremove the desired portion of the board.

After the cropping width and height of the board are determined the PCBis cropped according to the specifications. The width and height of thePCB may be cropped automatically based on the components used in thecircuit. PCB layout module 418 (See FIG. 4 and related discussion) mayautomatically determine where the components are placed on the PCB anddelete the portions of the board not used by the components.

While the component area sizes are shown for power circuits, othercircuits may utilize the predetermined landing area approach.Accordingly, the areas shown in the figures may be designed toaccommodate the different design requirements.

FIG. 28 illustrates the allocation areas of a PCB, according to anembodiment of the invention. As shown, PCB 2800 includes circuit board2805, inductor area 2810, output capacitor area 2815, diode area 2820,IC area 2825, small signal component area 2830, input capacitor area2835 and connection lines 2840.

Inductor area 2810 is sized such that there is sufficient area to placethe inductors used in the design of the circuit. Output capacitor areais sized such that there is sufficient area to place the outputcapacitors used in the design. Diode area 2820 is sized such that thereis sufficient area to place the diodes used in the design. IC area 2825is sized such that there is sufficient space to place the IC used in thedesign. According to one embodiment of the invention, the IC used in thedesign is placed in a fixed location on circuit board 2805. Small signalcomponent area 2830 is sized such that there is sufficient space toplace the small signal components used in the design. According to oneembodiment of the invention, the small signal components utilized areplaced at fixed locations within small signal component area 2830. Inputcapacitor area 2835 is sized such that there is sufficient area to placethe input capacitors used in the design.

FIGS. 29A and 29B illustrate exemplary PC board (PCB) layouts. The PCBlayout of the design is created such that the landing pads for thecomponents used are large enough to accommodate many different sizes andvarieties of surface mount components, which may vary from design todesign. Some of the parts, such as the IC may be through hole mount ifthese parts conform to a specific pin pattern specified for that board.This way, one PCB layout may be used for many different designs. Forexample, a PCB layout may be set up for the pinout of a specificNational Semiconductor device such as the LM2678. The copper tracesleading into this part are small since this part does not change in sizefrom design to design for that layout. However, to accommodate theessentially infinite number of combinations of accompanying components,which vary in size and shape, the landing pads for these components aremade large enough and spaced closely enough to accommodate the differentsizes of components foreseen for that PCB layout.

Building the Circuit

According to one embodiment, one or more of the web pages provided tothe user include a control which, when selected, invokes componentacquisition module 424. The component acquisition module 424, in turn,provides one or more component acquisition web pages to the user. Thecomponent acquisition web pages include information and/or controls forordering the components from which the generated circuit is constructed.

In the embodiment illustrated in the figures, a “Build It” link button2060 (See FIG. 20A) is provided which, when selected, provides componentacquisition web pages to the user. The component acquisition web pagepresented to the user in response to selection of build it button 2110may, for example, contain the information shown in FIGS. 22A and 22B.

FIGS. 22A and 22B show an exemplary BUILD IT web page. The build it pageincludes a bill of materials section that identifies the list of theparts used in the circuit. A user can check to see if the parts are instock and get pricing information for the components. Graphicalrepresentations of the components are also included in the bill ofmaterials if they are available.

Selecting button 2220 on the BUILD IT page allows the user to view anassembly diagram document for the board that shows the locations of allthe components and gives assembly and soldering instructions. Thisdocument may also be e-mailed to the user or made downloadable to theuser in various formats.

FIGS. 23A-23F illustrate an exemplary assembly diagram documentaccording to one embodiment of the invention. The assembly diagramdocument includes an assembly diagram, bill of materials, an electricalschematic, topside and bottom side copper lay out diagrams, andinstructions for building and testing the power supply. The assemblydiagram also includes buttons allowing the user to download the boardlayout or schematic in Protel format, and the Gerber file for making theboard. The information contained within the assembly diagram isautomatically created by the system.

Referring again to FIG. 22A, the user may select documentation relatingto the circuit by selecting documentation button 2210.

FIG. 24 shows an exemplary documentation page provided to the user afterselecting documentation button 2210. From the Design Doc link the usermay obtain the previously described assembly document. Also, by clickinglink 2440, the full documentation of the design (Design Document)including the specifications, operating values and thermal simulationresults can be obtained. A detailed summary of the integrated circuitwith links to the datasheet and application notes is available byselecting the Product Folder button 2420 associated with the selectedIC. Downloadable schematics, layout and Gerber files are also available.This enables the user to easily integrate the design into the user'slocal CAD environment. According to one embodiment of the invention, theschematic and layout files are in Protel format. According to otherembodiments of the invention, other layout formats may be provided. TheGerber file is for the custom board used for this design.

FIGS. 25A-25E illustrate an exemplary design document, according to oneembodiment of the invention. The design document includes many sections,including: an introduction; design specifications; schematic; operatingvalues; information on the selected IC; a bill of materials; thermalsimulation results; BuildIt! Information; and appendices includingadditional information, such as the number of thermal simulationsperformed on the design.

Returning to FIGS. 22A and 22B, when the user is has completed reviewingthe bill of materials and other information, the user may click on theOrder this Kit button 2230 to order the kit. According to oneembodiment, the party that would handle the order of a single componentwould be the manufacturer or distributor of the component. However, theparty that handles the “kit” order may be a third party. In response tothe order of a kit, the party from whom the kit is ordered placescorresponding component orders with the component manufacturers orobtains the parts from a local stock in a warehouse. The process ofplacing the corresponding component order can be executed automaticallyupon receipt and approval of a kit order.

If the user selects Order this Kit button 2230, the user will have theability to receive the components and bare PC board to make the circuit.However, the user may prefer to receive the circuit itself, alreadyassembled. Therefore, the user may alternatively or additionally bepresented with an “order built-up board” button (not shown), which, whenselected, causes the components, and optionally a PC board, to beordered and sent to a circuit board assembler. The circuit boardassembler assembles the circuit board from the ordered components anddelivers the custom-assembled circuit board to the user that placed theorder.

Under some circumstances, circuit board manufacturers may already haveprefabricated circuit boards that are similar to the automaticallydesigned circuit, or they may have to generate one specifically for thedesign. According to one embodiment, the server-side database includesinformation about such prefabricated circuit boards, and presents themto the user when the similarity between the prefabricated boards and theusers requirements exceeds a predetermined similarity threshold. Theprefabricated boards may be presented, for example, on the suggestedcomponent web page, the bill of materials web page, and/or the componentacquisition web page, or the thermal simulation launch page where theamount of copper area for each board option is presented as a parameterto the user.

Persistent Storage of Designs

A user may not be prepared to order the components of a circuit duringthe same session in which the circuit is generated for the user usingthe techniques described above. Therefore, according to one embodimentof the invention, a mechanism is provided for storing the designspersistently on a server-side storage device. The designs may be stored,for example, in a server-side database that associates the designs withthe user-id of the user that created the design. The event that triggersthe storage of a design in the database may be, for example, thecreation of the design or making a change in the design. Alternatively,a control may be provided which, when selected, causes the designs to besaved.

FIG. 26 shows an exemplary “my designs” page. The user may select the“My Designs” button included on one of the web pages. When a userselects my designs control, a saved designs web page that lists all ofthe saved designs for the user is presented to the user. The saveddesigned web page illustrated in FIG. 26 includes listings of a user'spreviously saved designs. The listing includes, for each saved design, adesign ID, a design name, the model number of the integrated circuitaround which the design is built, the creation date of the design,modification dates to the design, the name of the “design assistant”tool used to create the design, comments, and a design operation field.

Controls are provided to allow the user to modify, analyze, build, addnotes, delete, and share the design with a colleague. Selection of thecontrols may result in the delivery of an appropriate web page, asdescribed above. Selection of the delete, change name or add commentscontrols causes corresponding information to be deleted, changed, oradded to the server-side database.

The user may share a design with another user. For example, a first usermay select one or more of the first user's designs, and then specify oneor more second users with whom the design is to be shared. In response,the server-side database is updated to include a copy of the design forthe one or more second users. Also, an e-mail is sent to the seconduser(s) notifying them of the event. When one of the second users ispresented with a list of available saved designs, any designs that havebeen shared with the user are included in the list.

To share the design, the first user enters the e-mail of the seconduser(s). If the second user(s) in not currently registered for WEBENCH,a user ID and password are created for the new user and an e-mail issent to the new user to notify the second user(s) of the event.

System Overview

FIGS. 1-3 illustrate an exemplary environment for practicing theinvention. Aspects of the present invention are embodied in a World WideWeb (WWW) site accessible via the Internet according to one embodimentof the invention. Generally, the term “Internet” refers to the worldwidecollection of networks and gateways that use the Transmission ControlProtocol/Internet Protocol (“TCP/IP”) suite of protocols to communicatewith one another. At the heart of the Internet is a backbone ofhigh-speed data communication lines between major nodes or hostcomputers, including thousands of commercial, government, educational,and other computer systems, that route data and messages. Arepresentative section of the Internet 100 is shown in FIG. 1.

FIG. 1 shows a plurality of local area networks (“LANs”) 120 _(a-d) andwide area network (“WAN”) 130 interconnected by routers 110. Routers 110are intermediary devices on a communications network that expeditemessage delivery. On a single network linking many computers through amesh of possible connections, a router receives transmitted messages andforwards them to their correct destinations over available routes. On aninterconnected set of LANs—including those based on differingarchitectures and protocols—, a router acts as a link between LANs,enabling messages to be sent from one to another. Communication linkswithin LANs typically include twisted wire pair or coaxial cable, whilecommunication links between networks may utilize analog telephone lines,full or fractional dedicated digital lines including T1, T2, T3, and T4,Integrated Services Digital Networks (ISDNs), Digital Subscriber Lines(DSLs), wireless links including satellite links, or othercommunications links known to those skilled in the art. Furthermore,computers, such as remote computer 140, and other related electronicdevices can be remotely connected to either LANs 120 or WAN 130 via amodem and temporary telephone link. A remote computer may act in anumber of ways, including as a WWW server as described in FIG. 2 or aclient computer as described in FIG. 3. It will be appreciated that theInternet 100 comprises a vast number of such interconnected networks,computers, and routers and that only a small, representative section ofthe Internet 100 is shown in FIG. 1.

The media used to transmit information in communication links asdescribed above illustrates one type of computer-readable media, namelycommunication media. Generally, computer-readable media includes anymedia that can be accessed by a computing device. Computer-readablemedia may include computer storage media, communication media, or anycombination thereof.

Communication media typically embodies computer-readable instructions,data structures, program modules, or other data in a modulated datasignal such as a carrier wave or other transport mechanism and includesany information delivery media. The term “modulated data signal” means asignal that has one or more of its characteristics set or changed insuch a manner as to encode information in the signal. By way of example,communication media includes wired media such as twisted pair, coaxialcable, fiber optics, wave guides, and other wired media and wirelessmedia such as acoustic, RF, infrared, and other wireless media. TheInternet 100 may include networks constructed from, coupled to, orconnected with any type or combination of communication media.

The Internet has recently seen explosive growth by virtue of its abilityto link computers located throughout the world. As the Internet hasgrown, so has the WWW. Generally, the WWW is the total set ofinterlinked hypertext documents residing on HTTP servers around theworld. Documents on the WWW, called pages or Web pages, are typicallywritten in HTML (Hypertext Markup Language) or some other markuplanguage, identified by URLs (Uniform Resource Locators) that specifythe particular machine and pathname by which a file can be accessed, andtransmitted from server to end user using HTTP (Hypertext TransferProtocol). Codes, called tags, embedded in an HTML document associateparticular words and images in the document with URLs so that a user canaccess another file, which may literally be halfway around the world, atthe press of a key or the click of a mouse. These files may contain text(in a variety of fonts and styles), graphics images, movie files, mediaclips, and sounds as well as Java applets, ActiveX controls, or otherembedded software programs that execute when the user activates them. Auser visiting a Web page also may be able to download files from an FTPsite and send messages to other users via e-mail by using links on theWeb page.

A WWW server is a computer connected to the Internet having storagefacilities for storing hypertext documents for a WWW site and runningadministrative software for handling requests for the stored hypertextdocuments. A hypertext document normally includes a number ofhyperlinks, i.e., highlighted portions of text which link the documentto another hypertext document possibly stored at a WWW site elsewhere onthe Internet. Each hyperlink is associated with a URL that provides thelocation of the linked document on a server connected to the Internetand describes the document. Thus, whenever a hypertext document isretrieved from any WWW server, the document is considered to beretrieved from the WWW. As is known to those skilled in the art, a WWWserver may also include facilities for storing and transmittingapplication programs, such as application programs written in the JAVAprogramming language from Sun Microsystems, for execution on a remotecomputer. Likewise, a WWW server may also include facilities forexecuting scripts and other application programs on the WWW serveritself.

A user may retrieve hypertext documents from the WWW via a WWW browserapplication program. A WWW browser, such as Netscape's NAVIGATOR® orMicrosoft's INTERNET EXPLORER®, is a software application program forproviding a graphical user interface to the WWW. Upon request from theuser via the WWW browser, the WWW browser accesses and retrieves thedesired hypertext document from the appropriate WWW server using the URLfor the document and HTTP. HTTP is a higher-level protocol than TCP/IPand is designed specifically for the requirements of the WWW. HTTP isused to carry requests from a browser to a Web server and to transportpages from Web servers back to the requesting browser or client. The WWWbrowser may also retrieve application programs from the WWW server, suchas JAVA applets, for execution on a client computer.

FIG. 2 shows an exemplary WWW server 200 that is operative to provide aWWW site. Accordingly, WWW server 200 transmits WWW pages to the WWWbrowser application program executing on client computer 300 (FIG. 3) tocarry out this process. For instance, WWW server 200 may transmit pagesand forms for receiving information about a user, such as address,telephone number, billing information, credit card number, etc.Moreover, WWW server 200 may transmit WWW pages to client computer 300that allow a consumer to participate in a WWW site. The transactions maytake place over the Internet 100 or some other communications networkknown to those skilled in the art.

The WWW server 200 may include many more components than those shown inFIG. 2. However, the components shown are sufficient to disclose anillustrative embodiment for practicing the present invention. As shownin FIG. 2, WWW server 200 is connected to Internet 100, or othercommunications network, via network interface unit 210. Those ofordinary skill in the art will appreciate that network interface unit210 includes the necessary circuitry for connecting WWW server 200 toInternet 100, and is constructed for use with various communicationprotocols including the TCP/IP protocol. Typically, network interfaceunit 210 is a card contained within WWW server 200.

WWW server 200 also includes processing unit 212, video display adapter214, and a mass memory, all connected via bus 222. The mass memorygenerally includes RAM 216, ROM 232, and one or more permanent massstorage devices, such as hard disk drive 228, tape drive, optical drive226, and/or floppy disk drive. The mass memory stores operating system220 for controlling the operation of WWW server 200. It will beappreciated that this component may comprise a general purpose serveroperating system as is known to those of ordinary skill in the art, suchas UNIX, LINUX™, or Microsoft WINDOWS NT®. Basic input/output system(“BIOS”) 232 is also provided for controlling the low-level operation ofWWW server 200.

The mass memory as described above illustrates another type ofcomputer-readable media, namely computer storage media. Computer storagemedia may include volatile and nonvolatile, removable and non-removablemedia implemented in any method or technology for storage ofinformation, such as computer readable instructions, data structures,program modules or other data. Examples of computer storage mediainclude RAM. ROM, EEPROM, flash memory or other memory technology,CD-ROM, digital versatile disks (DVD) or other optical storage, magneticcassettes, magnetic tape, magnetic disk storage or other magneticstorage devices, or any other medium which can be used to store thedesired information and which can be accessed by a computing device.

The mass memory also stores program code and data for providing a WWWsite. More specifically, the mass memory stores applications includingWWW server application program 230. WWW server application program 230includes computer executable instructions which, when executed by WWWserver computer 200, generate WWW browser displays, including performingthe logic described above. WWW server 200 also has functional modules234, which perform logical operations as described below. WWW serverapplication program 230 may also create and transmit displays describedin conjunction with FIGS. 4-15. WWW server 200 may also include a JAVAvirtual machine, an SMTP handler application for transmitting andreceiving e-mail, an HTTP handler application for receiving and handingHTTP requests, JAVA applets for transmission to a WWW browser executingon a client computer, and an HTTPS handler application for handlingsecure connections. The HTTPS handler application may initiatecommunication with an external security application or a credit cardprocessing application for communicating with remote financialinstitutions in a secure fashion.

WWW server 200 also comprises input/output interface 224 forcommunicating with external devices, such as a mouse, keyboard, scanner,or other input devices not shown in FIG. 2. Likewise, WWW server 200 mayfurther comprise additional mass storage facilities such asCD-ROM/DVD-ROM drive 226 and hard disk drive 228. Hard disk drive 228 isutilized by WWW server 200 to store, among other things, applicationprograms, databases, and program data used by WWW server application230. For example, customer databases, product databases, imagedatabases, and relational databases may be stored. The operation andimplementation of these databases is well known to those skilled in theart.

FIG. 3 depicts several components of client computer 300. Clientcomputer 300 may include many more components than those shown in FIG.3. However, it is not necessary that those generally conventionalcomponents be shown in order to disclose an illustrative embodiment forpracticing the present invention. As shown in FIG. 3, client computer300 includes network interface unit 302 for connecting to a LAN or WAN,or for connecting remotely to a LAN or WAN. Those of ordinary skill inthe art will appreciate that network interface unit 302 includes thenecessary circuitry for such a connection, and is also constructed foruse with various communication protocols including the TCP/IP protocol,the particular network configuration of the LAN or WAN it is connectingto, and a particular type of coupling medium. Network interface unit 302may also be capable of connecting to the Internet through apoint-to-point protocol (“PPP”) connection or a serial line Internetprotocol (“SLIP”) connection as known to those skilled in the art.

Client computer 300 also includes BIOS 326, central processing unit 306,video display adapter 308, and memory. The memory generally includesrandom access memory (“RAM”) 310, read-only memory (“ROM”) 304 and apermanent mass storage device, such as a disk drive. The memory storesoperating system 312 and programs 334 for controlling the operation ofclient computer 300. Programs 334 may include programs described inconjunction with circuit design and ordering. The memory also includesWWW browser 314, such as Netscape's NAVIGATOR® or Microsoft's INTERNETEXPLORER® browsers, for accessing the WWW. It will be appreciated thatthese components may be stored on a computer-readable medium and loadedinto memory of client computer 300 using a drive mechanism associatedwith the computer-readable medium, such as a floppy drive (not shown),optical drive 316 or some other optical drive, or hard drive 318.Input/output interface 320 may also be provided for receiving input froma mouse, keyboard, or other input device. The memory, network interfaceunit 302, video display adapter 308, and input/output interface 320 areall connected to central processing unit 306 via bus 322. Otherperipherals may also be connected to central processing unit 306 in asimilar manner.

The above specification, examples and data provide a completedescription of the manufacture and use of the composition of theinvention. Since many embodiments of the invention can be made withoutdeparting from the spirit and scope of the invention, the inventionresides in the claims hereinafter appended.

1. A method for modifying an electrical design, comprising: creating afirst electrical design that includes components; wherein the firstelectrical design is created using communication between a client and aserver over the Internet; wherein the server performs the operations tocreate the design specified by receiving input from the client; andwherein the client displays at least a list of the components usedwithin the design that is received from the server; receiving, by theserver from the client, an input from a control that is located on a webinterface on the client that indicates a value along a scale; whereinthe value is indicative of a design tradeoff between optimization for afirst parameter and optimization for a second parameter; wherein thevalue places an emphasis on the first parameter and an emphasis on thesecond parameter; wherein the emphases affect the components selectedfor a second electrical design; such that when the value on the scale iscloser to the first parameter a larger emphasis is placed on the firstparameter of the second electrical design and when the value on thescale is closer to the second parameter a larger emphasis is placed onthe second parameter of the second electrical design; wherein the firstparameter is one of a set of parameters including footprint, cost,efficiency, thermal value, and power, and the second parameter is one ofthe set of parameters other than the first parameter; determining thesecond electrical design in response to the value indicated using thecontrol; automatically choosing components for the second electricaldesign; wherein at least one of the components chosen for the secondelectrical design are different from the components chosen for the firstelectrical design; and presenting at least the components for the secondelectrical design on the client.
 2. The method of claim 1, furthercomprising displaying operating values for the second electrical design.3. The method of claim 2, wherein the control is a knob control thatincludes at least five discrete values.
 4. The method of claim 3,wherein the second electrical design is determined in response toreceiving an input through a second control on the interface indicatingto optimize the circuit.
 5. The method of claim 1, wherein choosingcomponents comprises determining a score for components usable withinthe second electrical design; wherein determining the score comprisesdetermining how close each component is to a target value that is basedon the second electrical design.
 6. The method of claim 5, whereindetermining how close each component is to the target value that isbased on the second electrical design comprises examining at least twoof: a footprint parameter for the component; a resistance parameter forthe component; a capacitance parameter for the component; and aninductance parameter for the component.
 7. The method of claim 6,further comprising assigning a score for each parameter that is used forthe component.
 8. The method of claim 7, further comprising assigning aweight for each parameter that is used for the component.
 9. The methodof claim 8, further comprising determining a final score for each of thecomponents and selecting the component having the highest score; whereinthe highest score is a product of the score and the weight for the usedparameters.
 10. A non-transitory computer-readable storage mediumincluding computer executable instructions configured to cause at leastone device to perform a method for modifying an electrical design, theinstructions comprising instructions for: creating a first electricaldesign that includes components; wherein the first electrical design iscreated using communication between a client and a server over theInternet; wherein the server performs the operations to create thedesign specified by receiving input from the client; and wherein theclient displays at least a list of the components used within the designthat is received from the server; receiving, by the server from theclient, an input from a control that is located on a web interface onthe client that indicates a value along a scale; wherein the value isindicative of a design tradeoff between optimization for a firstparameter and optimization for a second parameter; wherein the selectedvalue places an emphasis on the first parameter and an emphasis on thesecond parameter; wherein the emphases affect the components selectedfor a second electrical design; such that when the value on the scale iscloser to the first parameter a larger emphasis is placed on the firstparameter of the second electrical design and when the value on thescale is closer to the second parameter a larger emphasis is placed onthe second parameter of the second electrical design; wherein the firstparameter is one of a set of parameters including footprint, cost,efficiency, thermal value, and power, and the second parameter is one ofthe set of parameters other than the first parameter; determining thesecond electrical design in response value indicated using the control;automatically choosing components for the second electrical design;wherein at least one of the components chosen for the second electricaldesign is different from the components chosen for the first electricaldesign; and presenting at least the components and operatingcharacteristics for the second electrical design on the client.
 11. Thecomputer-readable storage medium of claim 10, wherein choosingcomponents comprises determining a score for components usable withinthe second electrical design; wherein determining the score comprisesdetermining how close each component is to a target value that is basedon the second electrical design.
 12. The computer-readable storagemedium of claim 11, wherein determining how close each component is tothe target value that is based on the second electrical design comprisesexamining at least two of: a footprint parameter for the component; aresistance parameter for the component; a capacitance parameter for thecomponent; and an inductance parameter for the component.
 13. Thecomputer-readable storage medium of claim 12, further comprisingassigning a score and a weight for each parameter that is used for thecomponent.
 14. The computer-readable storage medium of claim 13, furthercomprising determining a final score for each of the components andselecting the component having the highest score; wherein the highestscore is a product of the score and the weight for the used parameters.15. A system for modifying a schematic over a network, comprising: aclient having a client network connection device, the client networkconnection device operative to connect the client and a user to thenetwork; a server having a server network connection device, the servernetwork connection device operative to connect the server to thenetwork; and a schematic device, operative to perform actions,including: create a first electrical design that includes components;wherein the first electrical design is created using communicationbetween a client and a server over the Internet; wherein the serverperforms the operations to create the design specified by receivinginput from the client; and wherein the client displays at least a listof the components used within the design that is received from theserver; receive, by the server from the client, an input from a controlthat is located on a web interface on the client that indicates a valuealong a scale; wherein the value is indicative of a design tradeoffbetween optimization for a first parameter and optimization for a secondparameter; wherein the selected value places an emphasis on the firstparameter and an emphasis on the second parameter; wherein the emphasesaffect the components selected for a second electrical design; such thatwhen the value on the scale is closer to the first parameter a largeremphasis is placed on the first parameter of the second electricaldesign and when the value on the scale is closer to the second parametera larger emphasis is placed on the second parameter of the secondelectrical design; wherein the first parameter is one of a set ofparameters including footprint, cost, efficiency, thermal value, andpower, and the second parameter is one of the set of parameters otherthan the first parameter; determine the second electrical design inresponse to the value indicated using the control; automatically choosecomponents for the second electrical design; wherein at least one of thecomponents chosen for the second electrical design is different from thecomponents chosen for the first electrical design; and display thecomponents and operating characteristics for the second electricaldesign on the client.
 16. The system medium of claim 15, whereinchoosing components comprises determining a score for components usablewithin the second electrical design; wherein determining the scorecomprises determining how close each component is to a target value thatis based on the second electrical design.
 17. The system of claim 16,wherein determining how close each component is to the target value thatis based on the second electrical design comprises examining at leasttwo of: a footprint parameter for the component; a resistance parameterfor the component; a capacitance parameter for the component; and aninductance parameter for the component.
 18. The system of claim 17,further comprising assigning a score and a weight for each parameterthat is used for the component and determining a final score for each ofthe components and selecting the component having the highest score;wherein the highest score is a product of the score and the weight forthe used parameters.